Oil temperature regulator



Sept. 21, 1948. D Es Er AL 2,449,696

OIL TEMPERATURE REGULATOR Filed Dec. 14, 1943 4 Sheets-Sheet 1 "sa' my L T- i [JEAWIR v 7 INVENTORS A oimsv R.

1 1943- W. H. GEDDES El AL 2,449,696

OIL TEMPERATURE REGULATOR 4 Sheets-Sheet 2 Filed D96. 14, 1943 MN Fa E Q t.

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w. H. GEDDES r AL OIL TEMPERATURE REGULATQR I 4 Sheets-Sheet 3 Filed Dec. 14, 1943 INVENTORTS 91m? A! 65005.;

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O NEY Sept. 21, 1948. H, GED ES L 2,449,696

OIL TEMPERATURE REGULATOR Filed Dec. 14, 1945 4 Sheets-Sheet 4 INVENTORS Ma 75/? /V. 65005:?

. 1 I I.siltizliiitm om. ncomes Walter H. Geddes and Phillip W. Schanke, Dayton, Ohio, minors to United Aircraft Products, Inc., Dayton, Ohio, a corporation of Ohio Application December 14, 1943, Serial No. 514,300 7 Claims. (01. 257-2) This invention relates to temperature regulating apparatus for use in a system circulating fluid under pressure and under conditions caus-' ing a progressive heating of the fluid. The invention has particular application to temperature regulators as used to obtain conditioning of the oil in the lubricating system of an internal combustion engine.

Oil 'temperature'regulators are in general use in aircraft, where it is their function to prevent overheating of the lubricating oil supplied to the enginel Their primary mode of operation is one of continuous cooling, and is effected by interposing 'in the oil line, apparatus wherein the oil flowsin heat exchange relationship with an assembly of air cooled tubes. Operation of the aircraft under varying flight conditions and at varying air temperatures makes it undesirable to subject the oil too cooling process at all times. Moreover, the tendency of excessively cooled o'ilto congeal results in the occasional formation of a restriction in the cooling passage through the tube assembly and the consequent attainment of high pressures in the oil lines, against the effects of which the regulator must be protected. The latter problem is complicated by the-fact that while the regulator must be protected from surgepressures and the like, warm oil at some pressure shouldbe admitted to "the tube assembly in order that congealed oil therein may be thawed and the cooling passage therethrough be reestablished.

Because of the requirements of oil temperature regulation regarding control ofthe oil flow, regulators customarily are provided with control devices including relief means for by-passing the oil around the cooling passage when the oil is not in need of cooling and when the pressure thereof rises above a safe level. Prior art control devices have a limited range of effectiveness in that-the regulator is inadequately protected against are hazards of cold weather starting and from surge pressures in general; deficiency of control resulting largely from the practice of relying on a single relief means which is placed beyond the point of entrance'to the cooling passage. Asa consequence the tube assembly is subject to all the varying pressures of the sys-- team. In some instances, as when starting the engine with the oil lines congealed, these pressures may rise well above the predetermined pressure designed to be maintained by the relief means.

The'principal object of this invention is to produce an oil temperature regulator having a generally new system of flow control, providing the regulator with pressure protection under all conditions of operation.

A more specific object of the invention is to cut on the cooling passage through the regulator from communication with the oil line until the oil flowing'in the line has been warmed to a predetermined temperature.

Another object is to prevent the tube assembly from being made subject to pressures higher than one predetermined to exercisethe desired thawing and expellingaction on congealedoil in the assembly.

A further object is to increase the degree of control had on the oil flow in order that it may be held more precisely to a predetermined temperature.

In carrying out these objects a practical embodiment of the invention has been developed in which a plurality of control devices have been combined in simple compact form in an oil temperature regulator of known construction, a feature of the combination being an arrangement placing one control assembly in advance of the entrance to the cooling passageway and a second control assembly beyond such entrance, with the first assembly functioning to divert surge pressures and cold viscous oil from 1 the passageway and the second assembly functioning to permit and prevent cooling within a relatively close range of oil temperatures and to limit the pressure applied to the oil in the tube assembly, I

Other objects and structural details of the invention will be apparent from-the following description when read in'connection with the accompanying drawings, wherein:

Fig. 1 is a view in perspective of an oil temperature regulator constructed in accordance with the present invention, part of the casing thereof being broken way to disclose the tube assembly;

Fig. 2 is a fragmentary top plan view of the regulator, showing in addition a diagram of an, engine lubrication system disclosing the place the regulator occupies in the system;

Fig. 3 is a view in vertical longitudinal section through the regulator, the air cooled tubes and certain bailles associated therewith being omitted, and the parts being shown as they appear with the engine idle and the oil below operating temperatures Fig. 4 is a fragmentary top plan view of the regulator. with the cast body of the manifold head removed to disclose the flange secured to the regulator casing;

Fig. is a fragmentary view in cross section, taken substantially along the line 5-5 of Fig. 3.

Fig. 6 is a view of the regulator head similar to Fig. 3, showing the parts as they appear after the oil has been heated sufilciently to require cooling; and

Fig. '7 is a view similar to Fig. 6, showing the parts as they appear under surge pressure.

Referring to Fig. 1, an oil temperature regulator of the class to which the invention relates comprises a cylindrical shell II encasing a core made up of a plurality of longitudinally extending spaced partitions I2 and heat exchange tubes I3 filling the spaces between the partitions. The ends of the tubes, l3 are expanded to a polygonal shape and occupy a nested relation with respect to each other, the arrangement being such that at the opposite ends of the core the tubes present a closed front while intermediate their ends within the shell II the tubes are spaced apart and define a maze for the passage of the oil which flows to and from the core through radial openings in the shell. To hold the tubes I3 in assembled relation and as a seal against the escape of oil from the core, the tube ends are secured together by a soldering operation. Similarly, the core is rigidly connected to the inner surface of the shell by means constituting a seal and a bond. The tubes I3 are open throughout their lengths for the passage of a coolant which may be fluid in any form. Conventionally, oil temperature regulators for aircraft are disposed in an air stream which passes through the core tubes, cooling the tubes and thereby the surrounding oil in the shell. The entry of the oil into the regulator and its discharge therefrom are effected through a manifold head l4 attached to, the outer surface of the shell II. The head I4 is provided with openings I5 and -I6 constituting the regulator inlet and outlet and which are placed in communication through alternative fluid passes leading respectively through the regulator core and in by-passing relation thereto. The former of said passes includes a series of vertical tubes I! which is centrally positioned in the shell II, the tubes serving the purpose of conveying the oil from the head I4 to an oppositely located chamber 18 formed within the shell through the cooperation of end sections I9 and a cover plate 2I (see also Fig. 3). The plate 2I has openings 20 therein (one shown) allowing the oil to pass from chamber I8 into the tube maze constituting the core proper. Under the influence of continuously applied pressure, the oil progresses through the core toward the head I4 and outlet I6 and in so doing contacts successive tubes I3 and is cooled. The partitions t2 serve as baflles for the oil and preferably are staggered in such manner as to cause the oil to move in a tortuous zig-zag path. Thus the oil enters each core section at one end thereof, travels lengthwise along the tubes I3 to the other end of the section and then around the end of the next adjacent bafile into the adjoining section toward the outlet.

The vertical tubes I1 extend through suitable openings in the baflies I2 and are arranged in a longitudinal row. The center space occupied by the row of vertical tubes is closed at the ends of the cores by channel members 22.

As indicated in Fig. 2, the oil temperature regulator is apart of the lubricant circulating system, being interposed between the engine 23 and reservoir 24 in position to condition the 011 after it leaves the engine and before its return to the reservoir. As shown, oil is delivered to the engine by way of a line 25, a pump 26 in the line acting to withdraw the oil from the reservoir and supply it to the engine under pressure. The oil leaves the engine by way of a line 21 connected to the inlet I5 of the oil temperature regulator, and after passing through the regulator continues on 'to the reservoir by way of a line 28 leading from the regulator outlet I6. A pump 29 in the line 21 acts as a scavenger in removing the oil from the engine and imparting to it a forced flow through the regulator to the reservoir. The pressure of the oil in the lines 21 and 28 and in the oil temperature regulator is at a minimum when the oil is in a warm fluid state and increases as a rising oil viscosity adds to the flow resistance. Thus, should the engine stand idle for several hours in a cold atmosphere, the oil in the lines and in the regulator around the air flow tubes I3 will congeal whereupon when the engine is next started a high pressure is established in back of the congealed oil as the pump 29 attempts to force oil from the engine past the restriction. Gradually, by the combination of such pressure and the warming effect of the hot oil from the engine, the restriction represented by the congealed oil is removed. During the process of such removal, however, it is desirable to limit the pressure applied to the oil in the regulator core in order that the tubes l3 which are thinly constructed, will not collapse or be distorted. Accordingly there is embodied in the head I4 a variety of protective means in the form of selective by-passes, automatic controls therefor being provided in order that a congealed regulator core may be subjected to a limited pressure and to a warming decongealing action when the pressure in the oil lines is normal or below a predetermined maximum and to prevent the application to the core of higher pressures such as may result from congelation in the line downstream of the regulator, as well as surge pressures arising from any causes and a check valve at the terminal ends of said primary and alternative flow paths for denying access of surge pressures in said auxiliary by-pass to said primary and alternative paths.

Referring to Fig. 3, the head I4 includes a cast body 3i attached to the flat upper surface of a flange 32 welded or otherwise secured to the shell II'. The flange 32 has a longitudinal channel 33 overlying the upper ends of the vertical tubes I1 which extend out of the core a short distance through the shell I I. Two spaced openings 34 and 35 in the flange establish commu- .nication between the channel 33 and points in the body 3|, while a third flange opening '36 (see Figs. 4 and 5) is cut off from the channel :33 by a rib 31 which has a longitudinal position astride one end of the row of tubes I1 to form an ex tension of the channel. The rib 31 defines on its opposite sides passages 38 (Fig. 5) adapted to register with shell openings 39 and so connect the regulator core to flange opening 36 and the communicating areas of the body 3|.

The body 3| is formed with internal walls which separate the interior of the body into a plurality of chambers, including a chamber 4| at the inlet I5 and a chamber 42 at the outlet I6 (see Fig. 5). Additional chambers, indicated at 43, 44 and 45 are formed opposite the respective flange openings 34, 35 and 36. The several chambers have ported entrances and exits for the passage of'theoil and are' arranged to provide a'plurality of fiow paths. Thus, oil entering the regulator is directed first to inlet chamber 4| and from there may pass through a port 45 to chamber 42 or through a port 41 to chamber 43, or it may pass through both ports simultaneously. Since chamber 42 communicates directly with the outlet, oil entering that chamber is discharged from the regulator. Oil entering the chamber 42 by way of port 45 in effect by-passes the regulator since this port in conjunction with chambers 4| and 42 constitutes a direct connection between the regulator inlet and outlet.

The oil leaving chamber 4| by way of port 41 passes through chamber 43 and registering flange port 34 into channel 93. Within the channel the oil may enter tubes i1 and begin a travel through the regulator core. or it may pass out of the channel through opening and enter body chamber 44.. Chamber 44 is'connected through a port 48 with chamber 45, and the latter chamber is connected through a port 49 with chamber 42 and .the outlet. 4 Hence, port 48 in conJunction with opening 85, chamber 44 and chamber constitute a passage by-passing the regulator core. In distinction from port 45, which by-passes the oil before it reaches the regulator core, the port .48 by-passes oil/at a point in free com1nunica- .tlon with the entrance to the core.

The oil within channel 33 which enters the vertical tubes I1 is directed to the chamber l8 on the opposite side of the shell from which it may escape through openings 28 in the plate 2| into thecore; Following the previously described tortuous path around the tubes i3 and past the ba'ilies |2,;the oil traverses the core and finally leaves the shell l| through openings 39 (Fig. 5). Then. passing through registering passages 38 in the flange 32 the oil flows out of flange opening and into the body chamber 45, the openlower end of' which is aligned with the opening 55. From chamber 45 the oil may pass through .port 49 to chamber 42 and the outlet. The oil flowing .to' chamber 45 from flange opening 55 is cooled. oil since it has passed through the regulator, core. Oil entering chamber 45 from flange opening 35, chamber 44 and port 48 is uncooled oil ,,'having come directly from the engine. v i In order to control the passage of the oil along the several flow paths above described, valve mechanism is provided, including a valve 5| mountedopposite the port 49 in a bushing cap 52 forming apart of the outer-wall of chamber 42. The valve 5| is of the poppet type, being pressed by a' spring 53 to a seated position closing the port 49 'and adapted to open under the pressure of the oil in. chamber 45 flowing to the outlet. It is intended that the valve 5| should function merely as a check valve, preventing any back pressure, which may be present at the outlet from being transmitted through chamber 45 to the regulator core.

Further included in the control valve mechanism are a unit 54 in the chamber 4| and a unit 55 in the chamber 45. The unit 54 comprises a pair of aligned valves 55 and 51 controlling respectively the port 48 and the port 41, while the unit 55 comprises a valve 58 controlling the port 48.- Considering first the unit 54, the valves 55 and 51 are secured respectively to aligned ele ments 59 and 5|. Element 59 is in the form of a valve stem and element 5| is in the form of a sleeve slidably mounted on a stub shaft 52 fixed in a plate 53 closing the end of the body 5| and constituting a part of the wall of chamber 48.

into and out of a position within the .port to cut on and establish communication between the chambers 4| and 42. The sleeve 5| has a flanged and locked in engagement with the adjacent end of the stem 55. which adjacent end is enlarged and recessed to accommodate a thermal substance 55. The substance 45 expands when heated and acts through a diaphragm 41 upon a rubber or rubber-like connector 45 between the diaphragm and a'cylindrical bearing 59 mounted on the stub shaft 52 and having a closed end abutting the shaft. Expansion of the thermal substance. 55 is transmitted through the connector 55 and bearing 59 as an axial force upon the stub shaft 82. The shaft 52 being immovable, such force efiects a reactive movement in a right hand direction, as viewed in Fig. 3, of the assembly comprising stem 59, sleeve 5| and valves 54 and 51. Movement so eflected tends to withdraw the valve 51 from the ort 41 and to cause the valve 55 to approach theport 45. Motion of the valve assembly under the compulsion of the thermal responsive substance 55 is opposed by a coil spring 1| interposed between thevalve 55 and a seat 12 in a wall'of the chamber 42. The valve 55 is adapted to close the port 45 by entering the port with a close fluid tight fit, and it further will be observed that, in the event oi. high oil pressures or from other causes, the valve may continue on through the port to again open it to the passage of oil.

Valve 58 of unit 55 in chamber 45 likewise is intended to be operated by thermal and pressure responsive means, and any of a variety of commercially known devices may be adoptedas the valve control unit. In the illustrated instance, the unit comprises a thermostat case 18 com taining two masses of a thermal responsive substance 14 which areallowed to expand in oppo-, site directions. Opposed sleeves 15 and "extend from the case 13 and surround respective stub shafts 11 and 15 which are adapted to be ex-. tended by the thermail substance acting through diaphragms 19 and resilient connectors 5|. The shaft 11 has the valve 58 secured to its outer end. while the shaft 18 is mounted for axial sliding movement in a housing 82 screw threaded in a bore in the wall of chamber 45. Confined within the housing 52 is a coil spring 83 which acts on the shaft 18 through a cup shaped washer 84 in a manner to resist extension of the shaft by the thermal means. Similarly,.extensionof the shaft 11 relatively to the sleeve 15 is resisted by a spring assembly 55. The force exerted by the spring assembly 85 is not effective to. prevent extension of. the shaft 11 but operates only to return the shaft when the thermal substance recedes from its expanded state. However, the spring 88 is relatively stronger and tends to hold shaft 18 against movement generated by the thermal substance; Accordingly, the fonces exerted by both masses 14 operate to move the valve 58 toward the port 48-the left hand or forward mass acting directly on the shaft 11, and the right hand or rearward mass tending to move the entire assembly including case 13 and sleeves 15 and 16, relatively to the housing 83. The spring 83 functions as a relief spring, allowing the valve 58 and associated parts to move rearward, away from the port 48 when a predetermined pressure is brought to bear on the valve.

In the operation of the oil temperature regulator, the parts tend normally to assume the positions shown in Fig. 3. Thus the valve assembly of unit 54 is shifted leftward by spring 1| to seat valve 51 in closing position and place valve 56 in open position, while valve 58 of unit 55 is in open position with respect to the port 48 by reason of the thermal substance 14 being cool or unheated. With the parts so arranged, the oil inlet [5 and oil outlet l6 are directly connected through port 48, white the passages leading to and from the regulator core are closed by the valves 51 and 5|. When the engine is first started the oil, which 118 not then in need of cooling, enters chamber 4| and, being prevented by the closed valve 51 from flowing to the regulator core, passes through port 46 to chamber 42 and outlet l6. Should the oiiwhich remained in the lines of the system during the period oftinued operation of the engine after it is started results in the oil discharged therefrom becoming progressively warmer, and such warmth transmitted to the thermal substance 66 causes expansion of the substance and movement of the assembly comprising valves 56 and 51 rightward (Fig. 3) against the pressure of spring 1|.

Port 41' thereby is opened and the oil entering the regulator'is free to pass into the skirted interior of the closure element 63 and through radial openings 85 therein to the flange channel 33. Until the valve 56 is moved far enough. to close the port 46 a portion of the oil will continue to be by-passed through port 46. When the port 48 is closed the entire oi l stream thereafter is directed through port 41 unless a restriction in the regulator causes a high pressure to develop, whereupon the valve 56 will be moved through and beyond port 46 to re-establish the by-pass (see Fig. 7). Within channel 33 the oil is permitted to flow both into the tubes l1 leading to chamber l8 and the regulator core, and through the by-pass port 48 to the outlet by way of chamber 45 and port 48. Within the chamber 45, the oil is in contact with the themnostat case 13 and as it gradually heats the thermal substance therein the valve 56 is moved to a seated position closing port 48. The parts then occupy the position shown in Fig. 6, and the oil stream is compelled to flow through the regulator core and restriction in the core a pressure which is high enough quickly to remove the. restriction but not sufllciently high to damage the air flow tubes l3. When the restriction has been removed the pressure immediately drops and valves 58 return to closed position.

The valve 58 also may be moved to open position by a cooling of the oil flowing around the thermostat case 13 from flange opening 38 and the regulator core. Accordingly, when the oil coming from the core drops below a predetermined temperature the vailve 58 will withdraw from port 48 and permit a by-passing of the oil until it is again in need of cooling.

To illustrate more clearly therelation between the operation of the valves and oil temperature. there may be described a commercial embodiment of the invention as applied to aircraft. The data given is not restrictive, however, as the parts may be made to operate in very different temperature ranges. The indicated device is designed to maintain the oil at an operating temperature of approximately F. When the oil is cold or not heated above a temperature of'106 it is passed directly to the outlet through port 48 and so circulates through the system without being cooled. At approximately 106 the assembly comprising valves 58 and 51 moves against the pressure of spring H to cause the former to approach port 46 and the latter to withdraw from port 41. Until an oil temperature of approximately 136 is reached the oil entering chamber 4! may flow both through port 48 and port 41. At 136 the port 46 closes and the entire oil stream is directed through port 41. Passing through port 41 the oil reaches flange channel 33 and from there may pass through the alternative paths represented by core inlet tubes i1 and by-pass port 48. Following the path of least resistance substantially all of the oil will by-pass through chamber 45 and around the thermostat case 18. As the oil temperature continuestogiSe the valve 58 moves toward port 48 and finally seats in a position closing the port as the temperature exceeds the predetermined figure of 160. All bypasses then are closed to the oil which accordingly is compelled to flow through tubes l1 to chamber l8 and thence through the cooling passage defined by the regulator core. The cooled oil is discharged to chamber 45 and flows past thermostat case 13 to the outlet. If the cooling obtained becomes excessive or greater than is necessary, the lowered temperature in chamber 45 will be reflected in a withdrawal of valve 58 to permit some or all of the oil to be by-passed through port 48.

As previously described the temperature control of the oil flow is supplemented by a pressure responsive control in order that the flow will not be interrupted by temporary freezing" of the oil.

or the core tubes damaged by high pressures resulting therefrom. Thus, both valves 58 and 58 will relieve under higher than normal pressures, a special feature of such arrangement residing in the fact that sudden surge pressures are largely dissipated through port 46 before they reach the core inlet. Port 48, which is located beyond the core inlet, therefore is not required to dispose-of any pressures except those under that degree necessary to force valve 56 through the port 48.

It will be understood that the invention is concerned with the liquid flow control devices of a liquid temperature regulator, rather than with the particular means by which cooling is obtained. Thus the invention is applicable to a variety of temperature regulators, including the so-called jacketed type wherein the casing is surrounded by a spaced jacket to define a passage which replaces the present tubes II in conducting the liquid to the core inlet and serves the further purpose of a warming by-pass. In either the jacketed or jacketless type regulators the invention may be used in conjunction with a diffusion method of decongealing, wherein warm oil is introduced into the core at spaced points between the inlet and outlet thereof. In the former instance this is done by means of radial ports in the casing, and in the latter instance by radial ports ID in the tubes W.

What is claime is:

1. In a liquid temperature regulator for controlling the temperature of a liquid which is progressively heated and which circulates under pressure to and from the heat generating means, said regulator being arranged for the passage of the liquid therethrough and having a manifold head formed with an inlet and an outlet; means in the regulator defining a liquid cooling passageway communicating at its opposite ends with said inlet and said outlet; a first conduit in said head leading from said inlet to said outlet in b'y-pass- 10 liquid passing through said first passageway, a second passageway connecting said inlet and said outlet, means responsive to a predetermined rise in the temperature of the liquid at said inlet for closing said second passageway and'opening said,

first passageway, a third passageway in communication with said first passageway'allowing the liquid to escape to the outlet in by-passing relation to said liquid cooling means, means acting in response to the attainment of a liquid temperature higher than said predetermined temperature for closing said third passageway, and a check valve between said outlet and the terminals of said first and third passageways preventing the application of back pressure to said first and third passageways from said second passag SW81?- 4. A liquid temperature regulator for use in a ing relation to said cooling passageway; a second conduit leading from said inlet to said outlet in by-passing relation to said cooling passageway and in continuous communication with said passageway; first and second valves in said first and second conduits respectively, each settable to effective and ineflective positions, in the former of which it blocks by-passing of the liquid; independently operable thermal means acting in response to rising liquid temperatures to move said first valve to effective position and then to move said second valve to effective position, and a check valve between said outlet and the terminals of said second conduit and said cooling passageway preventing the application of back pressure thereto from said outlet.

2. A liquid temperature regulator for controlling the temperature of a liquid which is progressively heated and which circulates under pressure to and from the heat generating means, comprising a regulator core including air cooled tubes defining therearound a liquid cooling passageway, the liquid around said tubes tending to congeal when excessively cooled; a casing surrounding said tubes and constituting the shell of the regulator core; and a head mounted on said casing for controlling the flow of liquid to and from said regulator core, said head including a primary fiow path to the core and an alternative flow path through which'the liquid may be by-passed relatively to the core in the event of congelation therein, pressure responsive means controlling said alternative path and operative to maintain the liquid pressure applied in said cooling passageway at a predetermined value, an auxiliary liquid by-pass encountered by the liquid before its passage through said primary or alternative flow paths, valve means responsive to the, temperature of the liquid entering the regulator for closing said auxiliary by-pass when the liquid is warmed to a pre-determined value and responsive to surge pressures to open said auxiliary by-pass, and means for denying access of surge pressures to said cooling passageway.

3. A liquid temperature regulator for use in a system in which the liquid is subjected to heat and circulated under pressure and having a liquid inlet and an outlet. a first passageway connecting said inlet and said outlet, means for cooling the and circulated under pressure, comprising a heat exchange portion and a surrounding casing, said casing having adjacent openings through which the liquid flows in passing to and from the heat exchange portion; a manifold head mounted on said casing in a, position overlying said adjacent openings and formed with ports constituting the inlet to the regulator and outlet therefromya first conduit in said head directly connecting said inlet and said outlet; a second conduit in said head indirectly connecting said inlet and said outlet, said second conduit communicating at a point intermediate its ends with the opening in 1 said casing through which the liquid flows in entering said heat exchange portion; a valve assembly responsive to the temperature of the liq- 'uid entering said inlet for controlling fiow through said first conduit and hrough said second conduit, said assembly being stationed at said inlet and normally operative to close said second conduit and open said first conduit; a chamber in said manifold head constituting the terminal end of said second conduit and communicating with said outlet and with the casing opening through which the liquid fiows in leaving said heat. ex-

change portion; a valve in said chamber operable' to close the terminal end of said second conduit by sh'utting off the flow into said chamber from said second conduit;- independently operable thermal means respectively in said chamber and at said inlet for operating said valves in sequence to obtain first the opening of said second conduit for fiow from said inlet, then the closing of said first conduit, and finally the closing of the terminal end of said second conduit, and a check valve between said outlet and said chamber.

5. A manifold head constituting an integral part of an oil temperature regulator for use in engine lubrication systems, said head being adapted to be mounted on the body of the regsaid regulator body having corresponding opens ings representing the inlet to the body and the outlet therefrom; partitions in said manifold head defining therein a first chamber communicating with said main inlet, a second chamber communicating with said main outlet, 3, third chamber communicating with the inlet to said body and a fourth chamber communicating with the outlet from said body; a first port connecting said first and second chambers; a second port connecting said first and third chambers; a, third port |connecting said second and fourth chambers; temperature controlled valves for controlling said fillet and second ports and operable when the oil l 1 temperature at said main inlet is below a predetermined value to open said first port and to close said second port and responding to a rising temperature above said value to open said second port and to close said first port; and a check valve controllin said third port to permit fiow therethrough only from said fourth chamber to said second chamber.

6. A manifold head constituting an integral part of an oil temperature regulator for use in engine lubrication systems, said head being adapted to be mounted on the body of the regulator and having openings representing the main inlet and the main outlet of the regulator, said regulator body having corresponding openings respectively connecting with said main inlet and said main outlet and marking the terminals of a cooling passageway; a passage between said main inlet opening and said main outlet opening communicatin with the opening in said regulator body marking the entrance to said cooling passageway; first and second temperature responsive valves in said passage respectively upstream and downstream relative to the opening in the regulator body marking the entrance to the cooling passageway, said first valve being constructed and arranged to permit flow thereby in response to rising oil temperature and said second valve being constructed and arranged to prevent flow thereby in response to a rising oil temperature; a port in said head directly connecting said main inlet opening and said main outlet opening; a third valve movable to a position within said port to prevent by-passing flow therethrough; means yieldingly holding said third valve in a position spaced from said port whereby to permit a by-passing flow of the liquid; means for moving said third valve into a position closing said port in accompaniment with motion of said first valve toward open position with respect to said passage; and means permitting movement of said third valve independently of said first valve through and beyond said port under a surge pressure to establish communication between said inlet and outlet irrespective of the position of said first valve or of the temperature oi' the oil.

7. A liquid temperature regulator for use in a system in which the liquid-is subjected to heat and circulated under pressure, comprising a heat bers communicating with respective openings in said casing; a check valve between said outlet chamber and the exit from said heat exchange portion preventing the application of back pressure to said heat exchange portion; a port in said head directly connecting said chambers; a valve assembly responding to the temperature and to the pressure of the liquid entering said inlet chamber for closing said port when the liquid temperature rises to a predetermined value and to open said port when the liquid pressure exceeds a predetermined value, irrespective of the liquid temperature, said assembly including a, valve movable under temperature control into said port and movable under pressure through and beyond said port. WALTER H. GEDDES, PHILLIP W. SCHANKE.

REFERENCES crrnn The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,992,796 Young Feb. 26, 1935 2,107,188 Ryder "Feb, 1, 1938 2,279,285 Worth Apr. 7, 1942 2,288,599 Ramsaur July 7, 1942 2,291,637 Kohlmann Aug. 4, 1942 2,322,047 Mormile June 15, 1943 2,352,704 Garner July 4, 1944 2,353,577 Magrum July 11, 1944 2,353,610 Chisholm July 11, 1944 2,354,371 Gill July 25, 1944 2,359,448 Shaw Oct. 1, 1944 2,374,639. Miller Apr. 24, 1945 2,396,053 McEntire Mar. 5, 1946 FOREIGN PATENTS Number Country Datev 350,065 Italy L July 5, 1937 419,023

Germany Sept. 26, 1925 

